J. Appl. Cryst.の発刊に際して

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Principles Of Fluorescence Spectroscopy

: The unpolarized absorption and circular dichroism spectra of the fundamental vibrational transitions of the chiral molecule, 4-methyl-2-oxetanone, are calculated ab initio. Harmonic force fields are obtained using Density Functional Theory (DFT), MP2, and SCF methodologies and a 5S4P2D/3S2P (TZ2P) basis set. DFT calculations use the Local Spin Density Approximation (LSDA), BLYP, and Becke3LYP (B3LYP) density functionals. Mid-IR spectra predicted using LSDA, BLYP, and B3LYP force fields are of significantly different quality, the B3LYP force field yielding spectra in clearly superior, and overall excellent, agreement with experiment. The MP2 force field yields spectra in slightly worse agreement with experiment than the B3LYP force field. The SCF force field yields spectra in poor agreement with experiment.The basis set dependence of B3LYP force fields is also explored: the 6-31G* and TZ2P basis sets give very similar results while the 3-21G basis set yields spectra in substantially worse agreements with experiment. jg

Ab initio calculation of vibrational absorption and circular dichroism spectra using density functional force fields

In this contribution to the special software-centered issue, the ORCA program package is described. We start with a short historical perspective of how the project began and go on to discuss its current feature set. ORCA has grown into a rather comprehensive general-purpose package for theoretical research in all areas of chemistry and many neighboring disciplines such as materials sciences and biochemistry. ORCA features density functional theory, a range of wavefunction based correlation methods, semi-empirical methods, and even force-field methods. A range of solvation and embedding models is featured as well as a complete intrinsic to ORCA quantum mechanics/molecular mechanics engine. A specialty of ORCA always has been a focus on transition metals and spectroscopy as well as a focus on applicability of the implemented methods to "real-life" chemical applications involving systems with a few hundred atoms. In addition to being efficient, user friendly, and, to the largest extent possible, platform independent, ORCA features a number of methods that are either unique to ORCA or have been first implemented in the course of the ORCA development. Next to a range of spectroscopic and magnetic properties, the linear- or low-order single- and multi-reference local correlation methods based on pair natural orbitals (domain based local pair natural orbital methods) should be mentioned here. Consequently, ORCA is a widely used program in various areas of chemistry and spectroscopy with a current user base of over 22 000 registered users in academic research and in industry.

The ORCA quantum chemistry program package

The scope of this review is the nature and dynamics of the singlet excited electronic states created in nucleic acids and their constituents by UV light. Interest in the UV photochemistry of nucleic acids has long been the motivation for photophysical studies of the excited states, because these states are at the beginning of the complex chain of events that culminates in photodamage. UV-induced damage to DNA has profound biological consequences, including photocarcinogenesis, a growing human health problem.1-3 Sunlight, which is essential for life on earth, contains significant amounts of harmful UV (λ < 400 nm) radiation. These solar UV photons constitute one of the most ubiquitous and potent environmental carcinogens. This extraterrestrial threat is impressive for its long history; photodamage is as old as life itself. The genomic information encoded by these biopolymers has been under photochemical attack for billions of years. It is not surprising then that the excited states of the nucleic acid bases (see Chart 1), the most important UV chromophores of nucleic acids, are highly stable to photochemical decay, perhaps as a result of selection pressure during a long period of molecular evolution. This photostability is due to remarkably rapid decay pathways for electronic energy, which are only now coming into focus through femtosecond laser spectroscopy. The recently completed map of the human genome and the ever-expanding crystallographic database of nucleic acid structures are two examples that illustrate the richly detailed information currently available about the static properties of nucleic acids. In contrast, much less is known about the dynamics of these macromolecules. This is particularly true of the dynamics of the excited states that play a critical role in DNA photodamage. Efforts to study nucleic acids by time-resolved spectroscopy have been stymied by the apparent lack of suitable fluorophores. In contrast, dynamical spectroscopy of proteins has flourished thanks to intrinsically fluorescent amino acids such as tryptophan, tyrosine, and phenylalanine.4 The primary UVabsorbing constituents of nucleic acids, the nucleic acid bases, have vanishingly small fluorescence quantum yields under physiological conditions of temperature and pH.5 In fact, the bases were frequently described as “nonfluorescent” in the early literature. * To whom correspondence should be addressed. E-mail: kohler@ chemistry.ohio-state.edu. Phone: (614) 688-3944. Fax: (614) 2921685. 1977 Chem. Rev. 2004, 104, 1977−2019

Ultrafast Excited-State Dynamics in Nucleic Acids

Electron paramagnetic resonance (EPR) spectroscopy provides a variety of tools to study structures and structural changes of large biomolecules or complexes thereof. In order to unravel secondary structure elements, domain arrangements or complex formation, continuous wave and pulsed EPR methods capable of measuring the magnetic dipole coupling between two unpaired electrons can be used to obtain long-range distance constraints on the nanometer scale. Such methods yield reliably and precisely distances of up to 80 A, can be applied to biomolecules in aqueous buffer solutions or membranes, and are not size limited. They can be applied either at cryogenic or physiological temperatures and down to amounts of a few nanomoles. Spin centers may be metal ions, metal clusters, cofactor radicals, amino acid radicals, or spin labels. In this review, we discuss the advantages and limitations of the different EPR spectroscopic methods, briefly describe their theoretical background, and summarize important biological applications. The main focus of this article will be on pulsed EPR methods like pulsed electron-electron double resonance (PELDOR) and their applications to spin-labeled biosystems.

https://www.cambridge.org/core/services/aop-cambridge-core/content/view/S003358350700460X

Long-range distance determinations in biomacromolecules by EPR spectroscopy.

Charge transfer in supramolecular assemblies of DNA is unique because of the notion that the pi-stacked bases within the duplex may mediate the transport, possibly leading to damage and/or repair. The phenomenon of transport through pi-stacked arrays over a long distance has an analogy to conduction in molecular electronics, but the mechanism still needs to be determined. To decipher the elementary steps and the mechanism, one has to directly measure the dynamics in real time and in suitably designed, structurally well characterized DNA assemblies. Here, we report our first observation of the femtosecond dynamics of charge transport processes occurring between bases within duplex DNA. By monitoring the population of an initially excited 2-aminopurine, an isomer of adenine, we can follow the charge transfer process and measure its rate. We then study the effect of different bases next to the donor (acceptor), the base sequence, and the distance dependence between the donor and acceptor. We find that the charge injection to a nearest neighbor base is crucial and the time scale is vastly different: 10 ps for guanine and up to 512 ps for inosine. Depending on the base sequence the transfer can be slowed down or inhibited, and the distance dependence is dramatic over the range of 14 A. These observations provide the time scale, and the range and efficiency of the transfer. The results suggest the invalidity of an efficient wire-type behavior and indicate that long-range transport is a slow process of a different mechanism.

/pdf/femtosecond-direct-observation-of-charge-transfer-between-348teiusxl.pdf

Femtosecond direct observation of charge transfer between bases in DNA

In a lot of cases active biomolecules are complexes of higher order, thus methods capable of counting the number of building blocks and elucidating their geometric arrangement are needed. Therefore, we experimentally validate here spin-counting via 4-pulse electron-electron double resonance (PELDOR) on well-defined test samples. Two biradicals, a symmetric and an asymmetric triradical, and a tetraradical were synthesized in a convergent reaction scheme via palladium-catalyzed cross-coupling reactions. PELDOR was then used to obtain geometric information and the number of spin centers per molecule in a single experiment. The measurement yielded the expected distances (2.2-3.8 nm) and showed that different spin-spin distances in one molecule can be resolved even if the difference amounts to only 5 A. The number of spins n has been determined to be 2.1 in both biradicals, to 3.1 and 3.0 in the symmetric and asymmetric triradicals, respectively, and to 3.9 in the tetraradical. The overall error of PELDOR spin-counting was found to be 5% for up to four spins. Thus, this method is a valuable tool to determine the number of constituting spin-bearing monomers in biologically relevant homo- and heterooligomers and how their oligomerization state and geometric arrangement changes during function.

Counting the monomers in nanometer-sized oligomers by pulsed electron-electron double resonance.

A pulsed electron paramagnetic resonance (EPR) spectroscopic ruler for oligonucleotides was developed using a series of duplex DNAs. The spin-labeling is accomplished during solid-phase synthesis of the oligonucleotides utilizing a palladium-catalyzed cross-coupling reaction between 5-iodo-2'-deoxyuridine and the rigid spin-label 2,2,5,5-tetramethyl-pyrrolin-1-yloxyl-3-acetylene (TPA). 4-Pulse electron double resonance (PELDOR) was then used to measure the intramolecular spin-spin distances via the dipolar coupling, yielding spin-spin distances of 19.2, 23.3, 34.7, 44.8, and 52.5 A. Employing a full-atom force field with explicit water, molecular dynamic (MD) simulations on the same spin-labeled oligonucleotides in their duplex B-form gave spin-spin distances of 19.6, 21.4, 33.0, 43.3, and 52.5 A, respectively, in very good agreement with the measured distances. This shows that the oligonucleotides adopt a B-form duplex structure also in frozen aqueous buffer solution. It also demonstrates that the combined use of site-directed spin-labeling, PELDOR experiments, and MD simulations can yield a microscopic picture about the overall structure of oligonucleotides. The technique is also applicable to more complex systems, like ribozymes or DNA/RNA-protein complexes, which are difficult to access by NMR or X-ray crystallography.

/pdf/a-peldor-based-nanometer-distance-ruler-for-oligonucleotides-42p240u2j1.pdf

A PELDOR-Based Nanometer Distance Ruler for Oligonucleotides

The central paradigm for the mechanistic understanding of biomolecular function is the idea that the structure and dynamics of a biomolecule determine its function. Of the methods capable of revealing structural data, X-ray diffraction has procured detailed information of large biomacromolecular complexes at atomic resolution. [1] However, it is not always possible to crystallize such large systems, and the structure in the crystal may not represent the functional state in solution. [2] High-resolution liquid-state NMR spectroscopy can be applied in solution and yields information about dynamics [3] but is currently restricted to systems smaller than approximately 50 kDa. Thus, for structural studies on large biomolecules in solution, other biophysical methods are required, for example fluorescence and electron paramagnetic resonance (EPR) spectroscopy. [4, 5] Both methods enable the measurement of distances on the nanometer scale between fluorophores or paramagnetic centers, respectively, giving access to domain arrangements and movements. In EPR spectroscopy, techniques based on pulsed electron– electron double resonance (PELDOR or DEER) [6] or double quantum coherence (DQC) [7] have been used to determine distances in the range of 1.5 to 8 nm with high accuracy. Especially PELDOR is commonly applied for nanometer distance measurements between nitroxides, cofactors, and metal centers and to count the number of monomers in aggregates. [8, 9] In both cases, the pulse sequences measure the

Olav Schiemann

Papers

Long-range distance determinations in biomacromolecules by EPR spectroscopy.

Femtosecond direct observation of charge transfer between bases in DNA

Counting the monomers in nanometer-sized oligomers by pulsed electron-electron double resonance.

A PELDOR-Based Nanometer Distance Ruler for Oligonucleotides

Relative orientation of rigid nitroxides by PELDOR: beyond distance measurements in nucleic acids.